JP2017026277A - Environment testing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an environment testing device that can reduce the maximum load current to suppress an increase in capacity of an earth leakage circuit breaker.SOLUTION: A control part 40 controls a low-temperature tank-side heater 26 and a high-temperature tank-side heater 36 not to actuate concurrently when a refrigeration machine 24 has actuated, thereby reducing the maximum load current and lowering a capacity of the earth leakage circuit breaker to be set.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an environmental test apparatus.

  As a background art of this technical field, the abstract of the following Patent Document 1 states that “the environmental test apparatus includes a blower, a refrigerator, a heater, a humidifier, a temperature controller, etc., and a heating output and a humidification output. When the total exceeds 100%, the output conversion unit that generates the control output converted to 100% in the ratio thereof, and the operation time that gives the converted output to the heater and the humidifier while shifting the time within the control cycle It has a heater / humidifier control device provided with a setting unit ".

Japanese Patent No. 2928162

The capacity of the earth leakage breaker used in the environmental test apparatus described in Patent Document 1 is determined based on the maximum load current when all the devices are operated simultaneously.
However, in reality, it is unlikely that all devices operate simultaneously, and the frequency according to the maximum load current is not often required. Even in such a case, a large capacity adapted to the maximum load current is required as the performance of the leakage breaker.
An object of this invention is to provide the environmental test apparatus which can suppress the increase in the capacity | capacitance of an earth-leakage circuit breaker.

  In order to solve the above problems, the present invention controls the low temperature tank side heater and the high temperature tank side heater so as not to be activated simultaneously when the refrigerator is activated.

ADVANTAGE OF THE INVENTION According to this invention, the environmental test apparatus which can reduce the capacity | capacitance of an earth-leakage circuit breaker can be provided.
Problems, configurations, and effects other than those described above will be clarified by the following embodiments.

1 is a schematic diagram of an environmental test apparatus according to a first embodiment of the present invention. 1 is a block diagram of an environmental test apparatus according to a first embodiment. It is a chart which shows the output of the heater output simultaneously with the environmental test apparatus as a comparative example in a time division unit. The flowchart which shows the process of the environmental test apparatus of 1st Embodiment. It is a time chart explaining the relationship between each tank temperature and the output of a heater in the environmental test apparatus of 1st Embodiment. It is a chart which shows the output of the heater for which simultaneous output was prohibited in the environment test device of a 1st embodiment in a time division unit. It is a chart which shows the output of the heater in which one was given priority in the time division unit in the environmental testing device of a 1st embodiment. The flowchart which shows the process which considered the minimum guarantee utilization factor in the environmental test apparatus of 2nd Embodiment. It is a chart which shows the output of the heater output simultaneously with a refrigerator stop state in the environmental test device of a 3rd embodiment in a time division unit.

(First embodiment)
(overall structure)
The configuration of the environmental test apparatus 1 according to the first embodiment of the present invention will be described below with reference to the schematic diagram of the configuration shown in FIG. 1 and the block diagram shown in FIG.
In FIG. 1, an environmental test apparatus 1 is provided in a low temperature tank 20, a test tank 10 in which a DUT 70 is disposed, a low temperature tank 20 that communicates with the test tank 10 through vent holes 28 and 29. Refrigerator 24, low-temperature tank blower 27, high-temperature tank 30 communicating with the test tank 10 through ventilation ports 38, 39, high-temperature tank heater 36 provided in the high-temperature tank 30, and high-temperature tank blower 37.

Further, as shown in FIG. 2, the control unit 40 includes the refrigerator 24, the high-temperature tank side heater 36, the high-temperature tank fan unit 37, the low-temperature tank side fan 52, the high-temperature tank side fan 62, the test tank temperature sensor 12, and the low-temperature tank temperature. The sensor 22 and the high-temperature tank temperature sensor 32 are connected to each other. The detailed configuration of the control unit 40 will be described later.
The test tank 10 includes a test tank temperature sensor 12 that detects the temperature of the gas (atmosphere) in the test tank 10. The test tank temperature sensor 12 detects the temperature data of the gas in the test tank 10 and outputs it to the control unit 40.
The cryostat 20 includes a cryostat temperature sensor 22. The low temperature bath temperature sensor 22 detects the temperature of the gas in the low temperature bath 20 and outputs temperature data of the detected gas to the control unit 40.

  In the low temperature tank 20 of the first embodiment, a low temperature tank side heater 26 is provided together with the refrigerator 24. The low temperature tank heater 26 corrects the cooling power of the refrigerator 24. The refrigerator 24 is controlled by the control unit 40 and is started together with the low temperature tank heater 26 or independently, and is switched alternately so as to be in the operation state and the stop state.

In the operating state, based on the temperature data of the gas (atmosphere) in the low-temperature tank 20 detected by the low-temperature tank temperature sensor 22 provided in the low-temperature tank 20, the control unit 40 receives the refrigerator from the output unit 48. A control signal for driving 24 is output. Further, the output unit 48 outputs a control signal for driving the low-temperature tank heater 26. Thereby, the inside of the low temperature tank 20 is cooled and reaches a precooling temperature (TL) which is a temperature necessary for a precooling state (accumulation of preheating). Furthermore, in the state where the low temperature test BLT is performed, the test tank temperature (A) is maintained at the temperature of the low temperature test tank (B).

The low temperature tank blower 27 includes a low temperature tank blower 52, a low temperature side blowing opening / closing damper 50 and a low temperature side suction opening / closing damper 51 capable of opening and closing the ventilation ports 28 and 29. The low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 of the first embodiment include actuators 54 and 55 that are operated by compressed air, an electric motor, or the like. The actuators 54 and 55 open and close the vent holes 28 and 29 by moving the low-temperature side blowing opening / closing damper 50 and the low-temperature side suction opening / closing damper 51 in the opening / closing direction in accordance with a control signal from the control unit 40.

The control unit 40 opens the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 in a state where the low temperature tank side blower 52 is driven, and is cooled into the low temperature tank 20 through the vent holes 28 and 29. Inject the gas to quench. By the driving of the low temperature tank side blower 52, the gas precooled through the low temperature tank 20, the vent hole 28, the test tank 10, and the vent hole 29 around the DUT 70 arranged in the test tank 10. Circulating, the temperature in the test chamber 10 is brought close to the low temperature test temperature (BL). Further, the control unit 40 closes the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 in a state where the low temperature tank side blower 52 is driven, so that the inside of the low temperature tank 20 in the precooled state (cold heat accumulation state). Can be circulated in the cryostat 20.

The drive control of the low-temperature tank side blower 52 may be performed independently, or the low-temperature side blowing opening / closing damper 50 and the low-temperature side suction opening / closing damper 51 may be opened and closed in synchronization. For example, the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 may be opened in synchronization with the driving of the low temperature tank side blower 52.
Further, the low temperature side blower opening / closing damper 50 and the low temperature side suction opening / closing damper 51 are closed in synchronism with the drive stop of the low temperature tank side blower 52 to block the gas flow between the test tank 10 and the low temperature tank 20. May be. In this case, the actuators 54 and 55 can be omitted. Furthermore, the mechanisms and operations of the low-temperature side blowing opening / closing damper 50 and the low-temperature side suction opening / closing damper 51 are not limited to the configuration of the first embodiment, and may be further simplified or omitted.

The said control part 40 controls the high temperature tank side heater 36 provided in the high temperature tank 30, and switches an operation state and a stop state alternately. In the operating state, the gas in the high-temperature tank 30 can be heated to a preheated state.
The high-temperature tank blower 37 is operated by a high-temperature tank blower 62, a high-temperature side blowing opening / closing damper 60 and a high-temperature side suction opening / closing damper 61 that can open and close the ventilation ports 38 and 39, compressed air, an electric motor, and the like. Actuators 64 and 65 are provided. Further, the control unit 40 opens the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61 in a state where the high temperature tank side blower 62 is driven, and is arranged in the test tank 10 through the ventilation ports 38 and 39. In addition, the gas in the high-temperature tank 30 in a preheated state can be sent around the object to be tested 70 and rapidly heated.
Further, the control unit 40 drives the high-temperature tank side blower 62 around the DUT 70 arranged in the test tank 10 through the high-temperature tank 30, the vent 38, the test tank 10, and the vent 39. The heated gas can be circulated to bring the temperature in the test chamber 10 closer to the high temperature test temperature (CH).
And the control part 40 closes the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61 in the state which is driving the high temperature tank side air blower 62, and makes the gas in the high temperature tank 30 in a preheating state the high temperature tank 30 It can be circulated within.

In the first embodiment, the actuators 54, 55 and 64, 65 that are operated by compressed air, an electric motor, or the like are used, but actuators of any configuration and drive system may be used.
For example, the low temperature side blower opening / closing damper 50, the low temperature side suction open / close damper 51, and the high temperature side blower opening / closing damper 60 may be opened / closed passively by wind power generated by driving the low temperature tank side blower 52 and the high temperature tank side blower 62. Any one that opens and closes the high temperature side suction opening and closing damper 61 may be used.

Furthermore, the low temperature side blowing opening / closing damper 50, the low temperature side suction opening / closing damper 51, the high temperature side blowing opening / closing damper 60, and the high temperature side suction opening / closing damper 61 may be opened / closed using hydraulic pressure, etc. The shape, quantity, and material of the drive source and transmission member used for transmission are not limited to the actuators 54, 55 and 64, 65 of the first embodiment.

(Configuration of control unit 40)
The said control part 40 switches the driving | running state and stop state of the said low temperature tank side air blower 52 and the high temperature tank side air blower 62 alternately. That is, based on the data detected by the test tank temperature sensor 12, the low temperature tank temperature sensor 22, and the high temperature tank temperature sensor 32, the control unit 40 mainly uses the refrigerator 24, the low temperature tank side heater 26, and the low temperature tank air blow. The low-temperature test BLT using the pre-cooling state using the unit 27 and the high-temperature test CHT using the pre-heating state mainly using the high-temperature tank side heater 36 and the high-temperature tank blowing unit 37 can be alternately performed.

The control unit 40 of the first embodiment shown in FIG. 2 includes an input unit 41, a calculation unit 42, a timer unit 44, a storage unit 46, and an output unit 48, and is an application developed in a RAM. The functions realized by the program are shown as a block diagram.
The input unit 41 receives temperature data detected by the test bath temperature sensor 12, the low temperature bath temperature sensor 22, and the high temperature bath temperature sensor 32. In addition to this, the input unit 41 is connected to an external input device such as a keyboard or a communication device (not shown), for example, data relating to test conditions and test results, high and low temperature test repetition counts, or two zones (high temperature test / low temperature test). Test) or three-zone test (high temperature test / normal temperature test / low temperature test), and test condition data such as high and low temperature setting temperatures may be input.

The calculation unit 42 includes hardware as a general computer such as a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and an HDD (Hard Disk Drive). , OS (Operating System), application programs, various data, and the like are stored. The OS and application program are expanded in the RAM, executed by the CPU, and perform arithmetic processing according to data input to the input unit 41 together with the timer unit 44 and the storage unit 46.
The timer unit 44 measures the low temperature test time and the high temperature test time during which control is performed based on the test condition data, or the elapsed time after reaching a desired temperature.
The storage unit 46 stores test condition data or temporarily stores temperature data detected by the test bath temperature sensor 12, the low temperature bath temperature sensor 22, and the high temperature bath temperature sensor 32, and is read and written by the calculation unit 42. Memory or buffer (both not shown).

The output unit 48 performs time-sharing control of the calculation processing results to the refrigerator 24, the low temperature tank side heater 26, the low temperature tank side fan 52, the high temperature tank side heater 36, and the high temperature tank side fan 62 connected to the control unit 40, respectively. Output a control signal. And the said refrigerator 24, the low temperature tank side heater 26, the low temperature tank side air blower 52, the high temperature tank side heater 36, and the high temperature tank side air blower 62 are each comprised so that a drive or a drive may be stopped according to a control signal. .
Further, the control unit 40, based on the temperature data detected by the test tank temperature sensor 12, the low temperature tank temperature sensor 22, and the high temperature tank temperature sensor 32, the refrigerator 24, the low temperature tank side heater 26, and the low temperature tank side blower 52. As long as it controls the driving of the high temperature tank side heater 36 and the high temperature tank side blower 62, these controls can be realized by dedicated hardware (such as an electronic circuit), and are realized by software. You can also

In this way, the control unit 40 outputs the control signal, whereby the gas in the low-temperature tank 20 that has been precooled by the low-temperature tank blower 27 and the high-temperature tank blower 37 is placed in the test tank 10. It is sent around the object 70. In addition, the control unit 40 sends the gas in the high-temperature tank 30 that has been in a preheated state around the DUT 70 disposed in the test tank 10. The environmental test apparatus 1 performs high and low temperature tests by repeating a high temperature test CHT and a low temperature test BLT constituting one temperature cycle C alternately and plural times under control of the control unit 40.

In the first embodiment, the low temperature side blowing opening / closing is controlled by controlling the driving of the actuators 54, 55, 64, 65 in accordance with the control signal output from the output unit 48 of the control unit 40 shown in FIG. The damper 50, the high temperature side blowing opening / closing damper 60, the low temperature side suction opening / closing damper 51, and the high temperature side suction opening / closing damper 61 are actively opened and closed.
For example, in the high temperature test CHT, the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 are closed, and the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61 are opened.
Further, in the low temperature test BLT, the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61 are closed, and the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 are opened.

In this way, the control unit 40 alternately opens and closes the low temperature side blowing opening / closing damper 50, the low temperature side suction opening / closing damper 51, the high temperature side blowing opening / closing damper 60, and the high temperature side suction opening / closing damper 61.
For example, when the high temperature side blow opening / closing damper 60 and the high temperature side suction opening / closing damper 61 are opened during the high temperature test CHT, the preheated gas in the high temperature tank 30 is driven to the immediately preceding state by driving the high temperature tank side blower 62. It is fed into the test tank 10 where the low temperature test BLT has been performed. The inside of the test tank 10 is at a low temperature test temperature (BL) in the immediately preceding low temperature test BLT.

For this reason, the periphery of the DUT 70 in the test tank 10 is rapidly heated and given a thermal shock. At this time, the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 close the ventilation ports 28 and 29 communicating between the low temperature tank 20 and the test tank 10. Thereby, the flow of gas between the test tank 10 and the low temperature tank is blocked.
Therefore, even if the refrigerator 24, the low temperature tank side heater 26, and the low temperature tank side blower 52 are driven in parallel during the high temperature test and precooling is performed in the low temperature tank 20, the DUT 70 in the test tank 10 is obtained. There is almost no effect on the ambient temperature.

In addition, the gas in the low-temperature tank 20 in the precooled state is sent into the test tank 10 where the high-temperature test CHT has been performed just before by driving the low-temperature tank-side blower 52. The inside of the test tank 10 is at a high temperature test temperature (CH) in the immediately preceding high temperature test CHT. For this reason, it cools rapidly and a cooling impact is given. At this time, the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61 close the ventilation ports 38 and 39 communicating between the high temperature tank 30 and the test tank 10. Thereby, the flow of gas between the high-temperature tank 30 and the test tank 10 is blocked.

Therefore, even if preheating is performed by driving the high-temperature tank side heater 36 and the high-temperature tank side blower 62 in parallel during the low temperature test BLT, there is almost no influence on the temperature around the DUT 70 in the test tank 10. . As described above, by alternately repeating the high and low temperature tests including the cooling thermal shock as one temperature cycle, the environmental test apparatus pre-cools or pre-heats the next test during the high and low temperature test BLT, and efficiently. A temperature cycle test of the DUT 70 can be performed.

The environmental test apparatus 1 that performs a low and high temperature test using such a temperature cycle may simultaneously operate a plurality of devices such as the refrigerator 24, the low temperature tank side heater 26, and the high temperature tank side heater 36.

FIG. 3 is a chart showing, in time-division units, a state in which the low temperature tank side heater 26 and the high temperature tank side heater 36 are simultaneously driven while the refrigerator 24 is driven. In this case, while the refrigerator 24 is always in operation, the low temperature tank side heater 26 (in this case, utilization rate = 30%) and the high temperature tank side heater 36 (in this case, utilization rate = 50%) are in operation at the same time. Thus, the load current flows through the three devices, and the total value becomes the maximum load current used when setting the capacity of the earth leakage breaker (not shown).

In consideration of such a possibility of being driven simultaneously, the environmental test apparatus sets the capacity of the earth leakage breaker based on the maximum load current when all the devices are operated.
However, even if it is assumed that there are few situations in which multiple devices operate at the same time, the maximum load current required during operation of all devices is maintained in order to maintain test accuracy and / or reliability of the test equipment. It is necessary to use an earth leakage circuit breaker having a large capacity based on it. The use of such a large-capacity earth leakage breaker has a problem in that the manufacturing cost increases.
Therefore, the environmental test apparatus 1 of the present invention controls the low temperature tank side heater 26 and the high temperature tank side heater 36 not to start simultaneously when the refrigerator 24 is activated, thereby reducing the maximum load current. As a result, the set capacity of the earth leakage breaker is reduced.

Specifically, when the refrigerator 24 is activated, the control unit 40 of the first embodiment is time-shared from the output unit 48 so that the low temperature tank side heater 26 and the high temperature tank side heater 36 are not driven simultaneously. Outputs control signals for control. And the time which overlaps can be eliminated by performing the control which shifts starting timing so that the drive time of the low temperature tank side heater 26 and the drive time of the high temperature tank side heater 36 may not overlap simultaneously.

For this reason, since the capacity of the earth leakage circuit breaker can be set using any one of the maximum load currents, the capacity of the earth leakage circuit breaker is small compared to the maximum load current that has been added up when all the heaters are used simultaneously. An earth leakage breaker can be used.
Moreover, the said control part 40 is comprised so that the low temperature tank side heater 26 or the high temperature tank side heater 36 of the side connected to the test tank 10 may be started preferentially among the low temperature tank 20 or the high temperature tank 30. Yes.

The flowchart shown in FIG. 4 explains the process performed by the control unit 40 in the environmental test apparatus 1 according to the first embodiment of the present invention. Further, a two-zone cycle test in which the high temperature test CHT and the low temperature test BLT are alternately performed without performing the normal temperature test will be described as an example.
Here, the utilization rate is a ratio indicating the output value output from the heater in the ON time by PWM control, and the utilization rate request is when the input unit 41 is artificially set. In addition, a required output specified based on temperature data detected by various sensors as described below, for example, what is set, such as how many times is heated or cooled, is shown.

When the two-zone cycle test of the environmental test apparatus 1 is started in step S1, the control unit 40 requests utilization rates of the high temperature tank 30 (high temperature tank side heater 36) and the low temperature tank 20 (low temperature tank side heater 26). Determine XR and YR (%). Specifically, the calculation unit 42 is based on a value given from the input unit 41 as a test condition or temperature data detected by the test bath temperature sensor 12, the low temperature bath temperature sensor 22, and the high temperature bath temperature sensor 32. The utilization rate requests XR and YR (%) are determined. At this time, since electric heaters are used as the low temperature tank side heater 26 and the high temperature tank side heater 36, the utilization rate requests XR and YR (%) are the response speeds of the low temperature tank side heater 26 and the high temperature tank side heater 36, or Utilization requirement XR and YR (%) are determined using the operable temperature range.

In step S2, the calculation unit 42 of the control unit 40 determines whether or not the combined value of the utilization rate requests XR and YR (%) exceeds 100%. If the combined value of usage rate requests XR and YR (%) does not exceed 100% (YES in step S2), the process proceeds to step S4, and calculation unit 42 uses usage rates X (%) and Y (%). To decide.
In step S4, the calculation unit 42 determines the usage rate of the high-temperature tank side heater 36 to be the same usage rate X (%) as the usage rate request XR, and also uses the usage rate of the low temperature bath side heater 26 as the usage rate request YR. It is determined as the utilization rate Y (%). These utilization factors X and Y (%) are stored in the storage unit 46, and the process is terminated.

On the other hand, when the sum of the utilization rate requests XR and YR (%) exceeds 100% in step S2 (NO in step S2), control unit 40 proceeds to step S3 and performs high temperature test CHT. It is determined whether it is in the middle.
If it is determined in step S3 that the high temperature test CHT is being performed, the control unit 40 proceeds to step S5, and if it is determined that the high temperature test CHT is not being performed (ie, the low temperature test BLT is being performed) The process proceeds to S6.

In step S <b> 5, the calculation unit 42 determines the utilization rate of the high-temperature tank side heater 36 as X (%) and also determines the utilization rate of the low-temperature tank side heater 26 as 100−X (%). The memory | storage part 46 memorize | stores these utilization rates X and 100-X (%), and complete | finishes a process.
Therefore, during the high temperature test CHT, the utilization rate request XR of the high temperature tank side heater 36 is set as the utilization rate X of the high temperature tank side heater 36 in preference to the low temperature tank side heater, and the test during the high temperature test CHT. A decrease in accuracy can be suppressed.

In step S6, the calculation unit 42 determines the utilization rate of the high-temperature tank side heater 36 to 100−YR (%) and also determines the utilization rate of the low-temperature tank side heater 26 as Y (%) = YR (%). And the memory | storage part 46 memorize | stores these utilization rates 100-YR and Y (%) = YR (%), and complete | finishes a process.

For this reason, during the low temperature test BLT, the utilization rate requirement YR of the low temperature tank side heater 26 is prioritized over the high temperature tank side heater 36. As a result, the low temperature tank side heater 26 on the side where the temperature control of the test tank 10 is controlled is driven in preference to the high temperature tank side heater 36, so that a decrease in test accuracy can be suppressed.

FIG. 5 is a time chart for explaining the relationship between each bath temperature and the output of the heater in the environmental test apparatus 1 of the first embodiment.
The time chart of FIG. 5 shows a test mode of a so-called two-zone cycle (a high temperature test zone, a low temperature test zone) in which the low temperature test BLT and the high temperature test CHT are alternately repeated with the time a to the time g as one temperature cycle C. Show.

Here, the vertical axis represents temperature (T), and the horizontal axis represents time (H). The test tank temperature (A) in one temperature cycle C1 is equal to the high temperature tank temperature (C) during the high temperature test CHT (time a to time g), and during the low temperature test BLT (time g to time i), The state of changing to be equal to the low temperature bath temperature (B) is shown.
Referring to FIGS. 1 and 2, the time chart of FIG. 5 will be described in time order. At time a, the test bath temperature (A) is the low temperature bath temperature during the low temperature test BLT performed by the previous temperature cycle C. The current temperature cycle C is started from the same constant low temperature test temperature (BL) as (B).

In FIG. 5, time a to time d indicate the high temperature test CHT period, and time d to time g indicate the low temperature test BLT period. In the current temperature cycle C, first, the high temperature test CHT is started at time a, and the vents 28 and 29 of the low temperature tank 20 are shut off by the low temperature side blowing open / close damper 50 and the low temperature side suction open / close damper 51. Then, cooling of the low temperature tank 20 is started.

And the control part 40 gives priority and starts the high temperature tank side heater 36 connected to the test tank 10 among the low temperature tank 20 or the high temperature tank 30 (time a).
In the high temperature test CHT period (time a to time d), at the time a to time b, the inside of the test tank 10 is rapidly heated using the high temperature tank side heater 36. Further, after the rapid heating (time b to time d), it is necessary to keep the test bath temperature (A) at the high temperature test temperature (CH).

For this reason, during the high temperature test CHT period (time a to time d), the utilization rate X of the high temperature tank side heater 36 is preferentially increased as compared with the utilization rate 100-X of the low temperature tank side heater 26.
That is, from time a to time b, the utilization rate of the high-temperature tank side heater 36 becomes a value close to 100%, but the temperature rise of the test tank 10 ends at time b.
During the period (time b to time d) in which the test bath temperature (A) is kept at the high temperature test temperature (CH), the utilization rate of the high temperature bath side heater 36 does not need to be close to 100% and is returned to a low value. The rapid heating period (time a to time b) is completed in a short time. For this reason, the low-temperature tank side heater 26 can be adjusted so that the low-temperature tank temperature (B) is not excessively lowered by quickly returning the low-temperature tank temperature (B) to the pre-cooling temperature (TL) (time c). .

Moreover, since the low temperature tank side heater 26 of the low temperature tank 20 that is not connected to the test tank 10 is not prioritized (time a to time c), the utilization rate 100-X is kept low. However, the low-temperature tank 20 and the test tank 10 are blocked by the low-temperature side blowing opening / closing damper 50 and the low-temperature side suction opening / closing damper 51. Therefore, the low temperature tank 20 can be protected from an excessive temperature drop. In order to prevent an excessive temperature decrease, a minimum guaranteed utilization factor m, which will be described later, may be set for the low-temperature tank heater 26.

Next, the low temperature test BLT period (time d to time g) shown in FIG. 5 will be described.
In FIG. 5, during the low temperature test BLT period, the refrigerator 24 raises the low temperature bath temperature (B) to the low temperature test temperature (BL) while giving a supercooling impact (time d to time e) to the DUT 70. Then, it is necessary to keep the test bath temperature (A) constant as the low temperature test temperature (BL) (time e to time g). For this reason, during the low temperature test BLT period (time d to time g), it is necessary to prioritize the utilization rate Y of the low temperature tank side heater 26 over the utilization rate X (%) of the high temperature tank side heater 36.

Therefore, the control unit 40 preferentially activates the low temperature tank side heater 26 connected to the test tank 10 out of the low temperature tank 20 or the high temperature tank 30 (time e to time g). Thereby, an overshoot can be prevented and the refrigerator 24 can be protected from overcooling. At this time, at time e, the refrigerator 24 can stop driving when the test bath temperature (A) reaches the low temperature test temperature (BL). For this reason, simultaneous driving of the high-temperature tank side heater 36 and the low-temperature tank side heater 26 may be allowed between the time e and the time f.

Further, in preparation for the thermal shock test of the next temperature cycle C, during the low temperature test BLT period (time d to time g), the high temperature tank side in the high temperature tank 30 is set to the set preheating temperature (TH). After raising using the heater 36, it is necessary to maintain preheating.
For this reason, the required utilization rate 100-Y of the high temperature tank side heater 36 is temporarily larger (time d to time f) than the utilization rate Y of the low temperature tank side heater 26. However, the vents 38 and 39 provided between the high temperature tank 30 and the test tank 10 are blocked by the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61. Therefore, the temperature adjustment by the high temperature tank side heater 36 does not affect the low temperature test BLT performed in the test tank 10.

Further, the gas in the high temperature tank 30 is blocked from the gas in the test tank 10 by the high temperature side blowing opening / closing damper 60 and the high temperature side suction opening / closing damper 61. For this reason, the test accuracy is not affected. Thus, during the low temperature test BLT period, the utilization rate Y of the low temperature tank side heater 26 is prioritized over the utilization rate X of the high temperature tank side heater 36, and the refrigerator 24 is protected.
Then, when the high temperature tank 30 is connected to the test tank 10 again in the next temperature cycle C, in the period (time g to time h), direct heating by the high temperature tank side heater 36 and preheating in the high temperature tank 30 are performed. Is used to increase the test tank temperature (A) of the test tank 10. For this reason, priority is given to the utilization factor X of the high temperature tank side heater 36.
Thus, one of the low-temperature tank side heater 26 or the high-temperature tank side heater 36 on the side connected to the test tank 10 is activated with priority. Thereby, since the low temperature tank side heater 26 and the high temperature tank side heater 36 are not started simultaneously, the maximum load current can be reduced and the capacity of the earth leakage circuit breaker can be reduced.

FIG. 6 shows the time-division of the relationship between the output of the refrigerator current and the current of the low-temperature tank heater 26 and the current of the high-temperature tank heater 36 for which simultaneous output is prohibited in the environmental test apparatus 1 of the first embodiment. It is a chart shown in units (refer to YES in step S2 in FIG. 4).
When the refrigerator 24 is activated, the control unit 40 of the first embodiment is configured so that the low temperature tank side heater 26 and the high temperature tank side heater 36 are not driven simultaneously, that is, the total utilization rate is 100%. A control signal for time division control is output from the output unit 48 so that the low temperature tank side heater 26 and the high temperature tank side heater 36 are not driven at the same time even if not exceeding.

In addition, the start time of the low temperature tank side heater 26 (for example, 30%) and the driving time of the high temperature tank side heater 36 (for example, 50%) are overlapped by performing control to shift the start timing. Time is decreasing.
For this reason, the capacity | capacitance of an earth-leakage circuit breaker can be set using the larger maximum load current (for example, 50% of electric current of a high temperature side) among the low temperature tank side heater 26 or the high temperature tank side heater 36.
Therefore, compared with the case where the maximum load current of the low temperature tank side heater 26 and the maximum load current of the high temperature tank side heater 36 are combined, the maximum load current of the environmental test apparatus 1 can be reduced, and the earth leakage is interrupted. The manufacturing cost of the vessel can be reduced.

FIG. 7 shows that in the environmental test apparatus 1 of the first embodiment, one of the refrigerator current, the current of the low temperature tank heater 26 for which simultaneous output is prohibited, and the current of the high temperature tank side heater 36 is prioritized. 6 is a chart showing the relationship in time division units (see YES in step S2 in FIG. 4).
When the refrigerator 24 is activated, the control unit 40 of the first embodiment sends a time division control control signal from the output unit 48 so that the low temperature tank side heater 26 and the high temperature tank side heater 36 are not driven simultaneously. Output.

And the test tank 10 is connected among the low temperature tank 20 or the high temperature tank so that the driving time of the low temperature tank side heater 26 and the driving time of the high temperature tank side heater 36 overlap at the same time and the utilization rate does not exceed 100%. The controller 40 forcibly decreases the utilization rate of the heater of the other tank (here, the non-prioritized high-temperature tank 30) with priority given to one tank (here, the low temperature tank 20). .
In FIG. 7, priority is given to the utilization rate (40%) of the low temperature tank side heater 26, and the utilization rate (80%) of the high temperature tank side heater 36 is reduced to 60% so that the total value does not exceed 100%. ing.

Thereby, the time w during which the low temperature tank side heater 26 and the high temperature tank side heater 36 are driven in an overlapping manner can be eliminated (w → 0). Thus, by reducing the utilization rate of the high-temperature tank side heater 36 (80% → 60%) and performing time-sharing control to shift the start timing, the total utilization rate is set to 100%, and the refrigerator 24 is driven. It is possible to reduce the capacity of the earth leakage breaker by setting a uniform maximum load current.

(Second Embodiment)
FIG. 8 shows processing by the environmental test apparatus 1 according to the second embodiment of the present invention. In addition, the same code | symbol is attached | subjected and demonstrated about the same thru | or equivalent part as the environmental test apparatus 1 of the said 1st Embodiment.

FIG. 8 is a flowchart showing processing in consideration of the minimum guaranteed utilization rate in the environmental test apparatus 1 according to the second embodiment. In order to prevent an excessive temperature decrease, a minimum guaranteed utilization factor m described below may be set for the low-temperature tank heater 26.
When the two-zone cycle test of the environmental test apparatus 1 is started in step S11, the control unit 40 uses the utilization rate request XR (%) of the high temperature tank 30 (high temperature tank side heater 36), the low temperature tank 20 (low temperature tank). Together with the utilization rate requirement YR (%) of the side heater 26), the minimum guaranteed utilization rate m (%) of the low temperature tank side heater 26 is determined.

Here, the minimum guaranteed utilization rate m is a utilization rate (current output value) set to protect the equipment of the environmental test apparatus 1 from overcooling caused by the refrigerating capacity of the refrigerator 24. Specifically, The minimum current output value of the low-temperature tank heater 26 required for protecting the equipment by heating the low-temperature tank heater 26 provided on the low-temperature tank 20 side by driving is used (%). It is a representation.

Based on the value given from the input unit 41 as the test condition or the temperature data detected by the test bath temperature sensor 12, the low temperature bath temperature sensor 22, and the high temperature bath temperature sensor 32, the calculation unit 42 uses the utilization rate request XR ( %), YR (%), and minimum guaranteed usage rate m (%).
In step S12, the calculation unit 42 of the control unit 40 determines whether or not the sum of the utilization rate requests XR and YR (%) exceeds 100%. If the combined value of usage rate requests XR and YR (%) does not exceed 100% (YES in step S12), the process proceeds to step S13, and calculation unit 42 uses usage rates X (%) and Y (%). To decide.

In step S13, the calculation unit 42 determines the utilization rate of the high temperature tank side heater 36 to be the same utilization rate X (%) as the utilization rate request XR, and the utilization rate of the low temperature tank side heater 26 is the same as the utilization rate request YR. It is determined as the utilization rate Y (%). These utilization factors X and Y (%) are stored in the storage unit 46, and the process is terminated.

On the other hand, when the sum of utilization rate requests XR and YR (%) exceeds 100% in step S12 (NO in step S12), control unit 40 proceeds to step S14 and performs high-temperature test CHT. It is determined whether it is in the middle.
In step S14, when it is determined that the high temperature test CHT is being performed, the control unit 40 proceeds to step S15, and when it is determined that the high temperature test CHT is not being performed (low temperature test BLT is being performed), The process proceeds to S16.

In step S <b> 16, the calculation unit 42 determines the utilization rate of the high-temperature tank side heater 36 to 100−YR (%) and also determines the utilization rate of the low-temperature tank side heater 26 as Y (%) = YR (%). . And the memory | storage part 46 memorize | stores these determined utilization rates 100-YR (%) and YR (%), and complete | finishes a process.
In step S15, the calculation unit 42 determines the utilization rate of the high-temperature tank side heater 36 as XR (%) and also determines the utilization rate of the low-temperature tank side heater 26 as 100-XR (%). The storage unit 46 stores these determined utilization rates XR and 100-XR (%), and advances the processing to step 17.

In step S17, it is determined whether or not the value of 100-X (%) is smaller than the set minimum guaranteed usage rate m (%). Here, the minimum guaranteed rate is a limit value that does not further reduce the output of the heater. For example, by keeping the utilization rate of the low temperature tank side heater 26 about 10%, the low temperature tank 20 is overcooled. This is the lower limit of the output value that is not affected.
When calculation unit 42 determines that the value of 100−X (%) is smaller than the set minimum guaranteed usage rate m (%) (YES in step S17), control unit 40 advances the process to step S18. When the calculation unit 42 determines that the value of 100-X (%) is not smaller than the set minimum guaranteed usage rate m (%) (NO in step S17), the control unit 40 ends the process. (END).

In step S18, a correction considering the minimum guaranteed usage rate m is applied to determine the usage rate. In step S18, the calculation unit 42 determines the utilization rate of the high-temperature tank side heater 36 to 100-m (%) and also determines the utilization rate of the low-temperature tank side heater 26 as m (%). And the memory | storage part 46 memorize | stores these utilization rates 100-m and m (%) which were determined, and complete | finishes a process.

For this reason, for example, when the temperature drop of the low temperature tank 20 is quick, when the temperature of the low temperature tank 20 is close to the lower limit of the operable temperature, or when it is required to protect the refrigerator 24, or the test tank The minimum guaranteed utilization factor m can be set when the test accuracy decreases, such as when it takes time to increase the temperature of 10.
Further, the minimum guaranteed usage rate m may be made effective only when the temperature of the low-temperature tank 20 becomes a predetermined temperature or lower. However, if there is a possibility that the test accuracy may be lowered by setting the minimum guaranteed utilization rate m, for example, the temperature recovery time indicating the refrigeration performance of the refrigerator 24 is prolonged, so that the temperature test is not established. In addition, it is more desirable to also take control such as suppressing the capacity of the refrigerator 24 or stopping the refrigerator 24.
Other configurations and operational effects are the same as or equivalent to those of the first embodiment, and thus the description thereof is omitted.

(Third embodiment)
FIG. 9 is a chart showing, in time division units, the output of the heaters that are simultaneously output when the refrigerator is stopped by the environmental test apparatus 1 according to the third embodiment of the present invention. In addition, the same code | symbol is attached | subjected and demonstrated about the same thru | or equivalent part as the environmental test apparatus 1 of the said 1st, 2 embodiment.
FIG. 9 shows, for example, a state where the refrigerator 24 is stopped (refrigerator stopped) during the high temperature test CHT.
If the utilization rate Y of the low temperature tank side heater 26 and the utilization rate X of the high temperature tank side heater 36 are within 100 (%), they are included in the setting range of the maximum load current of the leakage breaker. In particular, when the refrigerator is stopped, the maximum load current of the earth leakage breaker can be set even if the current used in the low-temperature tank heater 26 or the high-temperature tank heater 36 is increased by the chiller current of the refrigerator 24 that decreases. There is no need to increase the temperature, and the low temperature tank side heater 26 and the high temperature tank side heater 36 can be driven simultaneously.

In FIG. 9, the low temperature tank heater 26 and the high temperature tank heater 36 are simultaneously driven by time-division control after the refrigerator stop time when the refrigerator current is lost. Accordingly, even when the refrigerator 24 is stopped, the low temperature tank heater 26 and the high temperature tank heater 36 are heated together during the high temperature test CHT, and it is possible to suppress a decrease in test accuracy. .

In addition, although the case where the total output value of the heater is less than 100% is illustrated in FIG. 9, the output total value of the low temperature tank side heater 26 and the high temperature tank side heater 36 is 100% or more. It may be.
Other configurations and operational effects are the same as or equivalent to those of the first embodiment, and thus the description thereof is omitted.

[Modification]
The present invention is not limited to the above-described embodiments, and various modifications can be made. The above-described embodiments are illustrated for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of an embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of an embodiment. Further, it is possible to delete a part of the configuration of each embodiment, or to add or replace another configuration. Examples of possible modifications to the above embodiment are as follows.

In each of the above embodiments, in the configuration of the environmental test apparatus 1 shown in FIG. 1, the low temperature side blowing opening / closing damper 50 and the low temperature side suction opening / closing damper 51 are opened and closed in synchronization with the drive control of the low temperature tank side blower 52. However, as long as the low-temperature tank side blower 52 is driven and stopped, the gas between the test tank 10 and the low-temperature tank 20 (or the high-temperature tank 30) is circulated and cut off. The air blower may be used.

3 has been described as a software process using a program executed by the control unit 40 shown in FIG. 2 in the above embodiment, but part or all of the process is shown in ASIC (Application Specific An integrated circuit (IC for specific application) or a hardware process using an FPGA (field-programmable gate array) may be used.
In the above embodiment, the normal temperature test is not performed, and the two-zone cycle test in which the high temperature test CHT and the low temperature test BLT are alternately performed has been described as an example, but when performing the so-called three zone cycle test in which the normal temperature test is performed. In addition, it may be applied to prohibit simultaneous output.

[Overview of composition and effect]
As described above, according to the environmental test apparatus in the embodiment, the control unit 40 prevents the low-temperature tank side heater 26 and the high-temperature tank side heater 36 from starting at the same time when the refrigerator 24 is activated. To do. For this reason, the capacity | capacitance of the earth leakage circuit breaker set can be reduced by reducing a maximum load current.

  Furthermore, the control unit 40 preferentially activates the low temperature tank side heater 26 or the high temperature tank side heater 36 on the side connected to the test tank 10 of the low temperature tank 20 or the high temperature tank 30. For this reason, it is possible to suppress a decrease in test accuracy by driving the low temperature tank side heater 26 or the high temperature tank side heater 36 on the side where the temperature control of the test tank 10 is performed.

Moreover, the control part 40 can set the minimum guarantee utilization factor m to the low temperature tank side heater 26 or the high temperature tank side heater 36 activated as the non-priority side. Thereby, the inside of the low-temperature tank 20 can be heated by driving the low-temperature tank-side heater 26 to protect equipment such as the refrigerator 24.
Furthermore, the control part 40 permits simultaneous starting of the low temperature tank side heater 26 and the high temperature tank side heater 36, when the refrigerator 24 has stopped. For this reason, the fall of a test precision can be suppressed further.

DESCRIPTION OF SYMBOLS 1 Environmental test apparatus 10 Test tank 12 Test tank temperature sensor 20 Low temperature tank 22 Low temperature tank temperature sensor 24 Refrigerator 26 Low temperature tank side heater 27 Low temperature tank ventilation part 28,29,38,39 Ventilation hole 30 High temperature tank 32 High temperature tank temperature sensor 36 High-temperature tank side heater 37 High-temperature tank air blower 40 Control part 41 Input part 42 Calculation part 44 Timer part 46 Storage part 48 Output part 50 Low temperature side blowing opening / closing damper 51 Low temperature side suction opening / closing damper 52 Low temperature tank side blowers 54, 55, 64 , 65 Actuator 60 High-temperature side blowing open / close damper 61 High-temperature side suction open / close damper 62 High-temperature tank-side blower 70 DUT

Claims (4)

A test chamber for placing the DUT;
A low temperature bath communicating with the test bath;
A low-temperature tank heater for heating the gas in the low-temperature tank;
A refrigerator that cools the gas in the low-temperature tank to a precooled state;
A high-temperature bath communicating with the test bath;
A high-temperature tank heater for heating the gas in the high-temperature tank to a preheated state;
A controller for controlling the refrigerator, the low temperature tank side heater, the high temperature tank side heater,
The control unit is an environmental test apparatus that controls the low temperature tank side heater and the high temperature tank side heater not to start simultaneously when the refrigerator is activated.   2. The environmental test according to claim 1, wherein the control unit preferentially activates the low-temperature tank side heater or the high-temperature tank side heater on the side connected to the test tank among the low-temperature tank or the high-temperature tank. apparatus.   The environmental test apparatus according to claim 2, wherein the control unit sets a minimum guaranteed usage rate for the low-temperature tank side heater or the high-temperature tank side heater activated as a non-priority side.   The environmental test apparatus according to claim 1, wherein when the refrigerator is stopped, the control unit permits simultaneous activation of the low temperature tank side heater and the high temperature tank side heater.

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